RU2655985C1 - Method of ultrasound non-destructive control of integrity of tanks and apparatus for its implementation - Google Patents

Abstract

FIELD: defectoscopy.

SUBSTANCE: using for non-destructive testing of integrity of oil tanks and other products by method of directed acoustic waves. Summary of Invention consists in that simultaneously or sequentially in the bottom and side walls of the reservoir direct transverse and longitudinal ultrasonic waves that carry information about the presence of defects in the article under investigation. Apparatus feature for method implementation is the ability to switch direction of vector of vibrational displacements of generated ultrasonic waves and possibility of moving acoustic system over surface of test tank without changing quality of dry acoustic contact of piezoelectric transducers with reservoir surface.

EFFECT: expansion of operational capabilities of method and apparatus by allowing simultaneous or sequential monitoring of bottom and side wall of tank, improving quality of acoustic dry contact of piezoelectric transducers with controlled surface of reservoir, as well as possibility of changing controlled zone of reservoir by means of positioning device while maintaining quality of acoustic dry contact of piezoelectric transducers with surface of reservoir.

7 cl, 5 dwg

Description

The invention relates to the field of non-destructive testing of the integrity of oil reservoirs and other products by the method of directed acoustic waves.

A known method for a similar purpose, which consists in the fact that in the bottom of the tank generate an ultrasonic Lamb wave and receive transmitted through the defect and scattered on the defect waves of the antenna array. After processing the received signals, the dimensions and coordinates of the defect in the bottom of the tank are determined / CN 202305480, class. G01N 29/04, G01N 29/07, 2012 /.

The disadvantage of the analogue of the method is the limitedness of its use by studies of only the bottom of the tank.

A known method for a similar purpose, which consists in sensing the bottom of the tank with directional ultrasonic waves and receiving ultrasonic waves that interacted with the defects of the tank, which judge the presence, shape and location of the defect in the tank / JPS 5975141, cl. G01N 29/38, G01N 29/44, 1984 /.

The disadvantage of the second analogue is also its limited use by monitoring the bottom of the tank.

The known method for a similar purpose, adopted as a prototype, which consists in generating longitudinal and transverse directed sounding waves in the tank material using an ultrasonic generator, receiving antenna arrays reflected from defects and transmitted defects, processing the signals received at the outputs of the antenna arrays, which determine sizes and location coordinates of the defect in the bottom of the tank / CN 101666783, cl. G01N 29/14, 2010 /.

The disadvantage of the prototype is the limited use of the control of the bottom of the tank.

Known equipment for non-destructive testing of the integrity of reservoirs, containing a transceiver acoustic system made in the form of an antenna array of piezoelectric transducers attached to a controlled portion of the reservoir to provide dry acoustic contact between the piezoelectric transducers and the surface of the reservoir and a hardware-software complex for switching and data interpretation / CN 202305480, class G01N 29/04, G01N 29/07, 2012; JPS 5975141, CL G01N 29/38, G01N 29/44 1984; CN 101666783, cl. G01N 29/14, 2010 /.

The technical solution in the last patent is taken as a prototype of the equipment.

The disadvantage of analogues and prototype in terms of equipment is weak acoustic contact of the piezoelectric transducers with the surface of the tank, the impossibility of non-destructive testing of the bottom and side of the tank at the same time and the lack of a positioning device that allows you to change the control zone.

The technical result obtained from the implementation of the inventions, in terms of the method and equipment, is to expand the operational capabilities of the method and equipment by obtaining the possibility of simultaneous or sequential control of the bottom and side of the tank.

In addition, in terms of equipment, the technical result from the implementation of the inventions is to improve the quality of the acoustic dry contact of the piezoelectric transducers with a controlled surface of the tank, as well as the ability to change the controlled area of the tank using a positioning device while maintaining the quality of the acoustic dry contact of the piezoelectric transducers with the surface of the tank.

This technical result is achieved due to the fact that in the method of ultrasonic non-destructive testing of the integrity of the tanks, which consists in generating longitudinal and transverse directed probe waves in the material of the tank using an ultrasonic generator, receiving the antenna arrays reflected from the defects of the tank and transmitted through defects, processed by antenna arrays the outputs of the antenna arrays of signals, as a result of which the dimensions and coordinates of the location of the defect in the bottom of the tank are determined, ult sonic waves generate simultaneously or sequentially in the bottom and side wall of the tank adjacent to the bottom, and with the simultaneous generation of ultrasonic waves in the bottom and side wall of the tank generate ultrasonic waves with different directions of the particle vibrational velocity vector, and when processing the signals received at the outputs of the antenna arrays determine the size and location of the defect in the side wall of the tank adjacent to its bottom.

The technical result is also achieved due to the fact that the equipment for ultrasonic non-destructive testing of the integrity of the reservoirs containing a transceiver acoustic system made in the form of antenna arrays of piezoelectric transducers attached to the monitored portion of the reservoir to ensure dry acoustic contact of the piezoelectric transducers with the surface of the reservoir, and software -a hardware complex for switching and data interpretation, additionally contains a pos device positioning, made in the form of a flexible substrate with grooves, and the antenna arrays are made in the form of removable modules of piezoelectric transceivers installed in the grooves of the positioning device, while the clamping device is made in the form of magnetic cores installed in removable modules of the antenna arrays, and piezoelectric transceivers transmitting transducers - with the ability to switch the direction of the vector of vibrational displacements of the generated and received ultrasonic waves.

Piezoelectric transducers in removable antenna array modules are staggered.

Magnetic cores are installed in removable modules of antenna arrays between the transducers in a checkerboard pattern.

Around each piezoelectric transducer antenna arrays installed protective cuffs.

To enhance the dry acoustic contact of the piezoelectric transducers with the surface of the tank, each of the piezoelectric transducers of the antenna arrays is spring-loaded.

A flexible substrate with longitudinal grooves is made of vinyl plastic, fixed to the tank with magnets embedded on the substrate flush with the inner surface.

The invention is illustrated by drawings.

In FIG. 1 shows a diagram of apparatus for implementing the method; in FIG. 2, 3, 4 - diagrams of the performance of individual equipment nodes; in FIG. 5 is a simplified diagram of the implementation of the method of ultrasonic non-destructive testing of tank integrity.

The equipment for detecting defects in tanks contains a transceiver acoustic system made in the form of piezoelectric transducers combined into removable modules 1 of antenna arrays (Fig. 1, 2, 3), attached to the junction of the side wall with the bottom of the tank using a clamping device in the form of magnetic circuits 2 (Fig. 2) to ensure dry acoustic contact of the piezoelectric transducers with the outer surface of the tank.

There is also a device for positioning modules 1 of antenna arrays, made in the form of a belt 3 with grooves 4 (Fig. 1).

Antenna arrays, made in the form of removable modules 1 (Fig. 1, 2, 3), installed in the grooves 4 of the belt 3, are pressed to the surface of the tank using the magnetic circuits 2.

For the same purpose (providing the necessary clamping force) inside the module 1 case, each piezoelectric transceiver 5 (Fig. 2, 3) is equipped with a spring mechanism (not shown in the drawings).

To prevent moisture, dust or dirt from getting inside the module 1 case, a protective sleeve is provided around each converter 5 (not shown in the drawings).

Piezoelectric transducers in each removable module 1 (Fig. 2, 3) are installed in a checkerboard pattern. The magnetic circuits 2 in the removable modules 1 between the piezoelectric transducers 5 are also installed in a checkerboard pattern.

This allows you to enhance the technical effect by increasing the pressing force of each piezoelectric transducer in the module to the surface of the tank.

The belt 3 with grooves 4 can be made of vinyl plastic, fixed to the tank using magnets (not shown in the drawings).

The clamping device for providing acoustic contact of the piezoelectric transceivers 5 with the surface of the tank are magnetic cores 2 and the spring mechanism not shown in the drawings inside the module 1 housing.

The equipment also contains a switching module 6 to ensure the joint operation of the modules 1 of the piezoelectric transducers (Fig. 1), which is connected to a managed computer. Together with the computer, the module 6 for switching form a hardware-software complex for switching and data interpretation.

The switching module 6 is connected to the piezoelectric transducers 5 of the modules 1 by wires 7. Each of the transducers 5 is in contact with the protectors 8.

Piezoelectric transceivers 5 are configured to switch the direction of the vector of vibrational displacements of ultrasonic waves.

Such a converter, for example, is presented in patent / RU 2082163. G01N 29/24, 1997 /.

The housing 9, filled with a liquid damper 10, has a cover 11 (Fig. 4).

Two identical piezoelectric transducers are installed in the housing 9. The housing 9 is also equipped with a tread 8 having the shape of a cone or pyramid for contacting with the outer surface of the tank.

The findings of the piezoelectric transducers 5 are connected to the switching module 6.

The switching module 6, in addition to ensuring the joint operation of the piezoelectric transducer modules 1 (Fig. 1), allows converters 5 to be connected in phase or out of phase. In the first case, longitudinal waves are emitted, and in the second, transverse.

In FIG. 4 horizontal and vertical arrows represent the vibrational movements of the tread 8 in the x and y directions, respectively, and a dot in the z direction. With such oscillations in different directions, longitudinal and one of the polarization of the transverse ultrasonic waves will be generated.

Using the described equipment, the method of non-destructive testing of the integrity of the reservoir 12 (Fig. 5) is implemented as follows.

At the junction of the bottom 13 and the side wall 14 of the tank 12 is installed transceiver acoustic system 15 of the equipment.

Using a hardware-software complex of equipment in the bottom 13 and side walls 14 of the tank 12, the acoustic system 15 directs longitudinal and transverse ultrasonic waves, respectively, for example, transverse in the bottom and longitudinal in the side walls.

Longitudinal waves 17 in the side wall implement an echo method. Reflecting from the defect 16, part of the wave returns to the speaker system 15, carrying information on the coordinates and dimensions of the defect 16.

The transverse waves 18 in the bottom 13 implement simultaneously the acoustic, shadow method and the echo method, which allows you to reliably determine the presence and parameters of the defect 19 in the bottom 13 of the tank 12.

The equipment allows you to simultaneously or sequentially examine both the bottom and the side walls of the tank and monitor the tank from various places of installation of the equipment with high-quality acoustic dry contact of the piezoelectric transducers with a controlled surface of the tank.

This achieves the set technical result in terms of the method and apparatus as objects of inventions.

Claims (7)

1. The method of ultrasonic non-destructive testing of the integrity of the tanks, which consists in generating longitudinal and transverse directed sounding waves in the material of the tank using an ultrasonic generator, receiving the antenna arrays reflected from the tank defects and the transmitted ultrasonic wave defects, processing the signals received at the outputs of the antenna arrays, as a result of which determine the size and location of the defect in the bottom of the tank, characterized in that the ultrasonic waves generate simultaneously either directly or sequentially in the bottom and side wall of the tank adjacent to the bottom, and with the simultaneous generation of ultrasonic waves in the bottom and side wall of the tank, ultrasonic waves with different directions of the particle vibrational velocity vector are generated, and when processing the signals received at the outputs of the antenna arrays, the dimensions and the coordinates of the location of the defect in the side wall of the tank adjacent to its bottom. 2. Equipment for ultrasonic non-destructive testing of reservoir integrity, containing a transceiver acoustic system made in the form of antenna arrays of piezoelectric transducers attached to the monitored portion of the reservoir to ensure dry acoustic contact of the piezoelectric transducers with the surface of the reservoir, and a software and hardware complex for switching and interpretation data, characterized in that it further introduced a positioning device made in the form of g the side of the substrate with grooves, and the antenna arrays are made in the form of removable modules of piezoelectric transceivers installed in the grooves of the positioning device, while the clamping device is made in the form of magnetic cores installed in removable modules of the antenna arrays, and the piezoelectric transceivers are capable of switching the direction of the vector of vibrational displacements of the generated and received ultrasonic waves. 3. The equipment according to claim 2, characterized in that the piezoelectric transducers in the removable modules of the antenna arrays are staggered. 4. The equipment according to claim 3, characterized in that the magnetic cores are installed in removable modules of the antenna arrays between the transducers in a checkerboard pattern. 5. The equipment according to claim 2, characterized in that protective cuffs are installed around each piezoelectric transducer of the antenna arrays. 6. The equipment according to claim 2, characterized in that each of the piezoelectric transducers of the antenna arrays is spring-loaded. 7. The equipment according to claim 2, characterized in that the flexible substrate with longitudinal grooves is made of vinyl plastic that is mounted on the tank with magnets embedded on the substrate flush with the inner surface.

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